Adaptive quality of service policy for dynamic networks

ABSTRACT

A close-loop quality of service system is provided that collects real-time network performance indicators at the physical, data link and network layers. Using those indicators, the system dynamically controls the network traffic in order to achieve improved performance according to the priority and policy defined by a data user or system/network administrator. Several features of this quality of service system includes (1) dynamic maximum bandwidth reallocation, (2) dynamic maximum packet sizing, (3) adaptive policing, and/or (4) real-time link status feedbacks to make more efficient use of available bandwidth and adjust to transmission requirements.

This application is a divisional of U.S. patent application Ser. No.11/231,396, entitled “Adaptive Quality of Service Policy for DynamicNetworks,” inventors Liren Chen et al., filed Sep. 20, 2005, theentirety of which is incorporated herein by reference.

BACKGROUND

1. Field

Various features pertain to communication and/or data networks. At leastone implementation pertains to a method, system, and device forproviding quality of service information to adaptively allocate networkresources and modify traffic and priority policy.

2. Background

Communication networks serve to transfer various types of informationincluding data, voice, audio, video, or other forms of content andcontrol signals. The Open System Interconnection (OSI) model providesstructured layers to implement communications across a network. The OSIlayers define standards at each level of the network: physical (layer1), data link (layer 2), network (layer 3), transport (layer 4), session(layer 5), presentation (layer 6), and application (layer 7).

Because networks have a limited bandwidth through which to transfer thisinformation, they typically prioritize the order in which information istransmitted. This prioritizing of information on a network is commonlyused to guarantee a quality of service (QoS) or the particular type oftransmission (e.g., data, voice, video, etc.). For example,time-sensitive information, such as voice packets for a telephonic call,may be given priority over less time-sensitive information, such as textmessages.

The current technique to configure QoS support during setup of a givennetwork is to specify the committed bandwidth and priority for each typeof service. This works well on a network that has static bandwidth withstable link speed, and known or predictable latency and packet losscharacteristics. Conventional QoS techniques typically assume adedicated link speed, such as a T1 connection providing 1.5 Mbps orADSI, connection operating at about 100 Kbps. Bandwidth usageconfiguration usually happens during the setup of QoS policy and is noteasily adjustable after that point. A static link speed is assumed andused for rate-limiting configuration of one more service classes. Noreal-time feedback is available to make QoS policy adjustments when thebandwidth changes dynamically. This creates problems in implementing QoSwhen the link speed changes, as would be the case where the linkdegrades for instance. Thus, conventional QoS policy configurations areconservative in their bandwidth allocations and wasteful of networkresources, or overly ambitious in their bandwidth allocations andperform poorly in adverse link conditions,

For a network that has dynamic bandwidth characteristics, such as awireless network (e.g., an evolutionary data optimized (EVDO) network),the current QoS policy techniques would either be ineffective to policethe traffic or require an administrator to be way too conservative, andtherefore wasteful, with the precious network resources. That is, innetworks where the bandwidth may vary or the amount and types ofinformation transferred are unpredictable, it becomes difficult toallocate bandwidth among the services (e,g., data, voice, video, controlsignals, etc.) supported.

SUMMARY

A close-loop QoS system is provided at the network layer to collectreal-time network performance indicators at the physical, data link andnetwork layers. Using those indicators, the system dynamically controlsthe network traffic in order to achieve improved performance accordingto the priority and policy defined by a data user or system/networkadministrator. Several features of this QoS system includes (1) dynamicmaximum bandwidth reallocation, (2) dynamic maximum packet sizing, (3)adaptive policing, and/or (4) real-time link status feedbacks to makemore efficient use of available bandwidth and adjust to transmissionrequirements.

A method for adaptive bandwidth reallocation for quality of servicepolicy of a dynamic communication link is also provided comprising (a)receiving digital information from one or more sources, (b) organizingthe digital information into packets, each packet associated with one ofa plurality of service classes, (c) dynamically adjusting a quality ofservice policy to reallocate the maximum bandwidth per service class ifthe bandwidth of the dynamic communication link changes, and (d)transmitting the packets according to a predefined quality of servicepolicy. The method further comprises monitoring the real-time bandwidthcharacteristics of the dynamic communication link. The delivery prioritylevel associated with each packet is determined by the timingrequirements of the digital information contained in the packet. Themethod further comprises (a) dynamically adjusting a maximum packet sizefor the packets to maintain a maximum packet transmission time acrossthe dynamic communication link approximately constant, and (b)rearranging the order of packets to give time-sensitive packets greaterpriority if jitter is present.

Another embodiment provides a machine-readable medium having one or moreinstructions for implementing adaptive policing of digital informationpackets, which when executed by a processor causes the processor to (a)determine whether jitter is present in a dynamic communication link, and(b) rearrange the order of digital information packets to givetime-sensitive packets greater priority when jitter is present. Themachine-readable medium further comprises one or more instructions todetermine delivery priorities of a plurality of digital informationpackets.

Another embodiment provides a machine-readable medium having one or moreinstructions for sharing dynamic link status information across two ormore network stack layers, which when executed by a processor causes theprocessor to (a) implement two or more network stack layers to transmitdigital information of one or more service classes across the dynamiccommunication link; and (b) share dynamic link status information from afirst network stack layer with a second network stack layer. The firstnetwork stack layer is either the physical layer or data link layer of anetwork stack and the second network stack layer is the network layer.The machine-readable further comprising one or more instructions toobtain real-time link status feedback from a data link layer of thenetwork stack and apply it to quality of service operations at thenetwork layer of the network stack.

Several of the described features may also be implemented as part of oneor more apparatus or devices.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a communication system in which dynamic bandwidthand/or traffic reallocation policy adjustments may be implemented.

FIG. 2 illustrates is a block diagram of one implementation of acommunication device 200 that may be employed to perform bandwidthand/or traffic reallocation and policy adjustments.

FIG. 3 illustrates a method for adjusting the maximum bandwidth usageper service class on a gateway when dynamic bandwidth changes occur.

FIG. 4 illustrates a method for dynamic packet maximum sizing that maybe implemented on a gateway to adjust QoS policy.

FIG. 5 illustrates a method for adaptive policing that may beimplemented on a gateway to adjust QoS policy.

FIG. 6 illustrates one example of a communication system configured toprovide adaptive quality of service at a first and/or secondcommunication devices by implementing link status information across anetwork stack.

FIG. 7-11 illustrate other example apparatus that may be employed.

DETAILED DESCRIPTION

In the following description, specific details are given to provide athorough understanding of the embodiments. However, it will beunderstood by one of ordinary skill in the art that the embodiments maybe practiced without these specific detail. For example, circuits may beshown in block diagrams in order not to obscure the embodiments inunnecessary detail. In other instances, well-known circuits, structuresand techniques may be shown in detail in order not to obscure theembodiments.

Also, it is noted that the embodiments may be described as a processthat is depicted as a flowchart, a flow diagram, a structure diagram, ora block diagram. Although a flowchart may describe the operations as asequential process, many of the operations can be performed in parallelor concurrently. In addition, the order of the operations may berearranged. A process is terminated when its operations are completed. Aprocess may correspond to a method, a function, a procedure, asubroutine, a subprogram, etc. When a process corresponds to a function,its termination corresponds to a return of the function to the callingfunction or the main function.

Moreover, a storage medium may represent one or more devices for storingdata, including read-only memory (ROM), random access memory (RAM),magnetic disk storage mediums, optical storage mediums, flash memorydevices and/or other machine readable mediums for storing information.The term “machine readable medium” includes, but is not limited toportable or fixed storage devices, optical storage devices, wirelesschannels and various other mediums capable of storing, containing orcarrying instruction(s) and/or data.

Furthermore, embodiments may be implemented by hardware, software,firmware, middleware, microcode, or any combination thereof. Whenimplemented in software, firmware, middleware or microcode, the programcode or code segments to perform the necessary tasks may be stored in amachine-readable medium such as a storage medium or other storage(s). Aprocessor may perform the necessary tasks. A code segment my represent aprocedure, a function, a subprogram, a program, a routine, a subroutine,a module, a software package, a class, or any combination ofinstructions, data structures, or program statements. A code segment maybe coupled to another code segment or a hardware circuit by passingand/or receiving information, data, arguments, parameters, or memorycontents. Information, arguments, parameters, data, etc, may be passed,forwarded, or transmitted via any suitable means including memorysharing, message passing, token passing, network transmission, etc.

One feature provides quality of service (QoS) support according topredefined policies on networks that have dynamic bandwidth, networklatency and/or packet loss rates. One implementation of the QoS schemeis applied on top of the physical network to adapt to the real-timecharacteristics of the network and adjust the priority of differentservices dynamically based on pre-set policies.

A close-loop QoS system is provided at the network layer to collectreal-time network performance indicators at the physical, data link andnetwork layers. Using those indicators, the system dynamically controlsthe network traffic in order to achieve improved performance accordingto the priority and policy defined by a data user or system/networkadministrator. Several features of this QoS system includes (1) dynamicmaximum bandwidth reallocation, (2) dynamic maximum packet sizing, (3)adaptive policing, and/or (4) real-time link status feedbacks to makemore efficient use of available bandwidth and adjust to transmissionrequirements.

FIG. 1 illustrates a communication system in which dynamic bandwidthand/or traffic reallocation and policy adjustments may be implemented.One situation in which a dynamic bandwidth may be encountered is wheresome portion of the communications is performed over a wireless link.For example, a network communication device 102 wirelessly communicateswith other network devices 104 via a wireless communicationlink/interface 106. Communication device 102 may be a server configuredto operate as a gateway, router, bridge, and/or repeater, thatcommunicatively links one or more user devices 108, 110, 112 (e.g.,phones, computers, personal communication devices, personal digitalassistants, web browsers, etc.) to the rest of the network (e.g.,network device 104). The links between communication device 102 and theuser devices 108, 110, 112 may be either wireless or wired. Generally,communication device 102 receives information from user devices 108,110, 112 and forwards it over wireless link 106 to network device 104.Similarly, communication device 102 receives information over wirelesslink 106 and distributes it to the appropriate recipient user device108, 110, 112.

Network device 104 may be a server configured to operate as a gateway,router, bridge, and/or repeater. Both communication device 102 andnetwork device 104 may act as gateways for different subnets. In oneimplementation, traffic control QoS policy and advanced routing isapplied at communication device 102 and network device 104 to controltraffic in both directions. Generic routing encapsulation (GRE) may beapplied at each end (communication device 102 and network device 104)and a tunnel built between communication device 102 and network device104.

In one implementation, communication device 102 is located on anaircraft and communicates with various types of user devices 108, 110,112 on the aircraft Communication device 102 may act as a gateway tocommunicate with other wired or wireless networks (e.g., via gateway104). In this manner, user devices 108, 110, 112 are able to communicatebeyond the aircraft even when the aircraft is in flight. Network device104 may be a ground-based or air-borne gateway which enablescommunications with other ground-base or air-borne user devices orgateways.

FIG. 2 illustrates is a block diagram of one implementation of acommunication device 200 that may be employed to perform bandwidthand/or traffic reallocation and policy adjustments. Communication device200 may be used as communication device 102 in FIG. 1, and function as amodem, gateway, or network interface to provide a network link for oneor more local applications and/or devices. Communication device 200includes a local transceiver 202 and a corresponding first set ofreceive and transmit buffers 204 and 206 communicatively coupled to aprocessing unit 208. The processing unit 208 is also communicativelycoupled to a second set of receive and transmit buffers 210 and 212which are coupled to a network transceiver 214. The processing unit 208manages traffic between the local transceiver 202 and networktransceiver 214 and may be configured to implement several features,including (1) dynamic maximum bandwidth reallocation, (2) dynamicmaximum packet sizing, (3) adaptive policing, and/or (4) real-time linkstatus feedbacks to make more efficient use of available bandwidth(through the communication link of the network transceiver 214) on andadjust to transmission requirements. A memory device 216 may be coupledto the processing unit 208 to facilitate these traffic managementfunctions. Note that one or more of the components and functionsillustrated in FIG. 2 may be combined into a single component orembodied in several components without departing from the invention.

FIG. 3 illustrates a method for adjusting the maximum bandwidth usageper service class on a gateway, such as communication device 102, whendynamic bandwidth changes occur. As the distribution or types ofapplications communicating through communication device 102 changes, itbecomes wasteful to fix the bandwidth allocation to some set rate. Thus,communication device 102 is configured to recognize changes in thebandwidth and dynamically reallocate the bandwidth to more efficientlymake use of communication link 106.

Communication device 102 may be configured to dynamically allocate thebandwidth among various service classes or applications communicatingover the network. A determination is made on whether the bandwidthcapacity has changed 302. This may occur, for example, as a result ofenvironmental conditions that affect the quality oftransmissions/reception or other factors that degrade or improvecommunication link 106 and affect the bandwidth. In one implementation,this determination may be made by tracking signal-to-noise ratio'sand/or error rates on communication link 106. For instance, an increasein the packet retries or receive/transmit errors indicates a decrease inbandwidth capacity.

The communication device then determines the transmission raterequirements of traffic in reallocating the bandwidth 304. For instance,the maximum bandwidth allocations for each service class or applicationmay simply be proportional to the original/previous maximum bandwidthallocation for each service class or application. Thus, when thebandwidth increases or decreases, the maximum percentage allocated toeach service class or application remains the same. Alternatively,communication device 102 may also determine whether there have beenchanges in traffic requirements 306. For instance, the type and/ornumber of applications communicating through communication device 102over wireless communication link 106 may change over time. For example,communication device 102 may initially allocate fifty percent of thebandwidth of link 106 for voice (e.g., VOIP) communications and fiftypercent for web browsing applications. However, usage information mayindicate that voice communications account for greater bandwidth usagethan web browsing applications over link 106. Thus, better bandwidthusage may be achieved by reallocating the maximum bandwidth per serviceclass 308 to improve overall QoS. For example, a greater bandwidthpercentage (e.g., seventy percent) is allocated to voice communicationsversus web browsing applications (e.g., thirty percent).

Yet another implementation provides a discretionary denial-of-service tomaintain QoS for a dynamic bandwidth. For example, if the maximumallocated bandwidth for a particular service class or application canonly support two applications at their minimum communication rates, thencommunication device 102 may drop or deny service to any otherapplication of the same service class that attempts to communicate overthe allocated bandwidth. That is, rather than provide poor orineffective service to all applications, communication device 102 limitsthe number of applications or communication sessions supported at anyone time. This way, communication device 102 can at least guaranty aminimum transmission rate to some applications or services.

Yet another implementation provides for making the maximum bandwidth fora service class at least as large as the minimum bandwidth required fora single application or communication session. That is, rather thanmaking a maximum bandwidth for a service class so small that it cannotadequately support even a single application, the maximum bandwidth isallocated such that it is at least as large as the minimum bandwidthrequired for that service class or application.

Yet another feature provides for making a maximum bandwidth allocationan integer multiple of the minimum required bandwidth for thatparticular service class or application. For example, allocating amaximum bandwidth that is 3.5 times the minimum required bandwidth for aservice class may waste bandwidth when the communication channel isoperating at full-capacity (e.g., three applications/sessionscommunicating at the minimum rate,). To make better use of the overallbandwidth, it may be beneficial to make the maximum bandwidth allocationfor a service class an integer multiple of the minimum requiredbandwidth for that particular service class.

In some situations, the dynamic bandwidth may become so small that itbecomes impossible to provide a minimum bandwidth required to supportcertain classes of services. For instance, the overall dynamic bandwidthmay decrease so much that the maximum bandwidth allocated for aparticular service class is less than the required minimum bandwidth forthat service. In such situations, rather than allocating a uselessamount of bandwidth to a particular service class, that bandwidth isreallocated to other service classes that can benefit or make use ofthat bandwidth. As the dynamic bandwidth increases, the denied serviceclass may again receive a bandwidth allocation.

FIG. 4 illustrates a method for dynamic maximum packet sizing that maybe implemented on a gateway, such as communication device 102, to adjustQoS policy and address jitter in a communication link. Abrupt variationsin the available bandwidth result in unwanted timing jitter (e.g.,variations or instability in the duration of a specified time interval)of the transmission link, where transmission times increase and/ordecrease. This increase/decrease in link transmission time has anegative impact on the delivery of time-sensitive information, such asvoice over IP packets. In particular, it makes it difficult for thecommunication system to determine a maximum transmission delay so thatit can guarantee delivery of high priority packets.

One solution to such link jitter is to adjust the maximum packet size ofall information being transmitted so that the actual time oftransmission (or transmission delay) stays below a particular threshold.A determination is made as to the current jitter of the communicationlink 402. This may be done by measuring timing variations betweenreceived packets. Then, the current jitter is compared to the previousjitter 404 to determine if there has been a change in the communicationlink jitter 406. If there has been a change in the communication linkjitter, the maximum packet size of all packets transmitted is adjustedto compensate for the change in jitter 408. For example, if the timingjitter has increased above a particular threshold (meaning that themaximum packet transmission delay or time has increased above aparticular threshold), the maximum packet size of ail packets across thecommunication link is reduced to maintain the maximum transmission timeor delay approximately constant. In this manner, the system can have aguaranteed maximum transmission delay or time.

FIG. 5 illustrates a method for adaptive policing that may beimplemented on a gateway, such as communication device 102, to adjustQoS policy. This feature monitors jitter in the link 106 and arrangesthe transmission order of packets according to their time-to-user orpriority characteristics. When transmitting voice-over-IP (VOIP), forinstance, jitter may be experienced over the link that may degrade thequality of the conversation. For example, given a 1,500 Byte IP packetand a 120 kbps return link rate, it takes over 100 milliseconds to sendone packet. The VOIP packets would typically be interleaved betweenpluralities of other packets for other sessions. Jitter may cause someVOIP packets to experience noticeable delays and degrade a conversation.Thus, adaptive policing is implemented to counter this problem. Amechanism is provided to dynamically reset or adjust the quality ofservice (QoS) policy in order to control the network traffic based onpreset guideline(s).

In one example, traffic is shaped by classifying it into a plurality ofclasses in ascending or descending priority. For instance, traffic maybe classified, from highest priority to lowest priority, as follows: 1)voice control traffic, including Session Initiation Protocol (SIP) andnetwork control packets; 2) voice-bearing traffic, including Real-timeTransport Protocol (RTP) and voice carrying packets; 3) acknowledges,such as Internet Control Message Protocol (ICMP) and TransportCommunication Protocol (TCP) ACK's; 4) web browsing—hypertext transferprotocol (HTTP)—and other interactive applications; and 5) all theremaining traffic.

The timing requirements (e.g., time-to-user requirements) or trafficpriorities are determined for the various packets and/or session 502.For example, text data packets may require guaranteed delivery but canwithstand longer delays. Meanwhile, voice communications (e.g., VOIPpackets) can withstand dropped packets but have shorter delays.Generally, prior knowledge of applications is necessary in order toproperly shape the traffic priority.

The system may monitor a buffer to determine the characteristics of thepackets therein. The presence of jitter in the communication link (e.g.,link 106 in FIG. 1) is also determined 504. This may be done bymeasuring tuning variations between received packets. If jitter greaterthan a particular threshold is detected 506, then the order of packetsin the buffer is adjusted to give time-sensitive packets greaterpriority 508. That is, time-sensitive packets are moved ahead of someless time-dependent packets. The system then continues to monitor thetiming requirements of packets and presence of jitter.

In one implementation, various fair queuing schemes (e.g., stochasticfair queuing) are applied to all queues such that the system randomly orpseudo-randomly extracts packets of different priority levels fortransmission. This prevents high-priority packets from monopolizing thelimited bandwidth to the detriment of other service classes orapplications,

Yet another feature of adaptive policing limits low priority traffic toa transmission rate less than the link speed and limits their burstrates. In this manner, the QoS for higher priority traffic can bemaintained.

FIG. 6 illustrates a communication system where real-time link statusinformation can be shared across layers of a network stack. The networkstack may be similar to an OSI model having an Application Layer (Layer7) 604, a Presentation Layer (Layer 6) 606, a Session Layer (Layer 5)608, a Transport Layer (Layer 4) 610, a Network Layer (Layer 3) 612, aData Link Layer (Layer 2) 614, and a Physical Layer (Layer 1) 616.Application layer 604 provides network services to end-users orapplications. Presentation layer 606 converts the local data to astandard byte representation. Session layer 608 defines the format ofthe data sent over the connections. Transport layer 610 subdivides thecontent in a user buffer into network-buffer sized datagrams andenforces a desired transport protocol. Network layer 612 is responsiblefor routing or directing datagrams from one network to another. Datalayer 614 defines the format of data on the network (e.g., data frame,packet, checksums, source and destination address, data., etc.) Physicallayer 616 defines the physical media employed for communications.

One implementation provides a mechanism to collect real-time link statusfeedback of the physical (Layer 1) and data link (Layer 2) layers at thenetwork layer (Layer 3). These network performance indicators are usedat the network layer (Layer 3) in order to decide the optimal policy topolice traffic through a gateway. That is, having real-time informationabout the link status may improve the performance of many of the QoSfeatures described above. In the standard OSI model, this information isfound in Layer 2 (Data. Link layer.) However, QoS is typicallyimplemented at higher layers, such as Layer 3 (Network layer). Thus, onefeature of the invention provides for access to link status information,such as packet sizes, data rates, dropped packet statistics, etc., to beaccessible at the Layer 3 or above. This may be done through softwarehooks that allow Layer 3 applications to retrieve link statusinformation from Layer 2.

An alternative technique provides a live monitoring mechanism thatcollects network layer (Layer 3) performance information for differentservice classes and provides closed-loop real-time feedback to controlthe QoS policy. This technique isolates the network layer (Layer 3)policy from the underlining physical network (Layer 2) and makes thistechnique adaptive to an EVDO network and other types of networks.

FIG. 6 illustrates one example of a communication system configured toprovide adaptive quality of service at a first and/or secondcommunication systems 600 and 602 by implementing link statusinformation sharing across a network stack. First and secondcommunication systems 600 and 602 are communicatively coupled to eachother via a network 618 (e.g., wired and/or wireless network) totransmit information. Each communication device or associated devicesmay implement a network stack that facilitates one or more of the QoSpolicy adjustment features described above. Thus, link statusinformation from the Physical layer (1) and Data Link layer (2) may beaccessible to Network layer (3) and used to improve communications atone or both sides of the communication link between communicationdevices A and B.

Communication systems 600 and 602 may include one or more systems thatimplement the network stack. For example, layers 1, 2, and 3 may beimplemented on a modem, router, or gateway while layers 4, 5, 6, and 7may be implemented on a personal communication device such as a mobilephone, computer, personal digital assistant, etc.

In one implementation, communication system 600 may be a gateway on anaircraft that serves one or more personal communication devices (e.g.,cell phones or computers) in the aircraft and provides a communicationlink to devices other communication devices inside or outside theaircraft (e.g., to other devices on land, inside the same aircraft, oron other aircraft). Using status link sharing across network stacklayers, communication system 600 may be configured to perform (1)dynamic maximum bandwidth reallocation, (2) dynamic maximum packetsizing, (3) adaptive policing, and/or (4) real-time link statusfeedbacks to make more efficient use of a bandwidth and adjust totransmission requirements as described above. Through the network stackone or more of these techniques may be implemented. These techniques maybe applied at various layers of the network stack illustrated in FIG. 6without departing from the invention.

FIGS. 7-11 illustrate examples of various other implementations toachieve various operations in accordance to the description above. InFIG. 7, a communication gateway may comprise a receiver module 710, anorganizer module 720, a monitor module 730 and an adjuster module 740.Receiver module 710 is configured to receive digital information.Organizer module 720 is configured to organize the digital informationinto packets, where each packet associated with one of a plurality ofservice classes. Monitor module 730 is configured to monitor real-timecharacteristics of a dynamic communication link to identify a change inbandwidth. Adjuster module 740 is configured to adjust a quality ofservice policy to reallocate the maximum bandwidth per service class, ifthe bandwidth of the dynamic communication link changes.

FIG. 8 illustrates an apparatus comprising a receiver module 810, aclassifier module 820, a monitor module 830, an adjuster module 840.Receiver module 810 is configured to receive digital information.Classifier module 820 is configured to classify the digital informationinto one or more service classes. Monitor module 830, is configured tomonitor real-time characteristics of a dynamic communication link havingvarying bandwidth. Adjuster module 840 is configured to dynamicallyadjust a quality of service policy for the one or more service classesaccording to the real-time characteristics of the dynamic communicationlink.

FIG. 9 illustrates an apparatus comprising a receiver module 910, asegmenting module 920, a monitor module, a determining module 940 and anadjustor module 950. Receiver module 910 is configured to receivedigital information. Segmenting module 920 is configured to segment thedigital information into packets. Monitor module 930 is configured tomonitor real-time characteristics of a dynamic communication link havingvarying bandwidth. Determining module 940 is configured to determine iftiming jitter of the dynamic communication link has changed. Adjustermodule 950 is configured to dynamically adjust a maximum packet lengthof the digital information to maintain a maximum packet transmissiontime approximately constant.

FIG. 10 illustrates another apparatus comprising a determining module1010 configured to determine whether jitter is present in a dynamiccommunication link and a rearranging module 1020 configured toadaptively rearrange the order of digital information packets to givetime-sensitive packets greater priority when jitter is present. FIG. 11illustrates still another apparatus comprising an implementer module1110 configured to implement two or more network stack layers totransmit digital information from one or more service classes across adynamic communication link and a sharing module 1120 configured to sharedynamic link status information from a first network stack layer with asecond network stack layer.

It should be noted that the gateway and apparatus of FIGS. 7-11 areexamples and may comprise other elements. Also, one or more of theelements of FIGS. 7-11 may be implemented together. Moreover, one ormore of the elements of FIGS. 7-11 may be implemented by various meansas necessary.

Accordingly, it should be noted that the foregoing embodiments aremerely examples and are not to be construed as limiting the invention.The description of the embodiments is intended to be illustrative, andnot to limit the scope of the claims. As such, the present teachings canbe readily applied to other types of apparatuses and many alternatives,modifications, and variations will be apparent to those skilled in theart. For instance, one or more of the components an&or functionsdescribed herein may be combined into a single component or embodied inmultiple components without departing from the invention.

1. A method for adaptive bandwidth reallocation for quality of servicepolicy of a dynamic communication link comprising: receiving digitalinformation from one or more sources; organizing the digital informationinto packets, each packet associated with one of a plurality of serviceclasses; dynamically adjusting a quality of service policy to reallocatethe maximum bandwidth per service class if the bandwidth of the dynamiccommunication link changes; and transmitting the packets according to apredefined quality of service policy.
 2. The method of claim 1 furthercomprising: monitoring the real-time bandwidth characteristics of thedynamic communication link.
 3. The method of claim 1 wherein thedelivery priority level associated with each packet is determined by thetiming requirements of the digital information contained in the packet.4. The method of claim 1 further comprising: dynamically adjusting amaximum packet size for the packets to maintain a maximum packettransmission time across the dynamic communication link approximatelyconstant; and rearranging the order of packets to give time-sensitivepackets greater priority if jitter is present.
 5. An apparatus foradaptively reallocating bandwidth for quality of service policy of adynamic communication link comprising: means for receiving digitalinformation from one or more sources; means for organizing the digitalinformation into packets, each packet associated with one of a pluralityof service classes; means for dynamically adjusting a quality of servicepolicy to reallocate the maximum bandwidth per service class if thebandwidth of the dynamic communication link changes; and means fortransmitting the packets according to a predefined quality of servicepolicy.
 6. The apparatus of claim 5 further comprising: means formonitoring the real-time bandwidth characteristics of the dynamiccommunication link.
 7. The apparatus of claim 5 wherein the deliverypriority level associated with each packet is determined by the timingrequirements of the digital information contained in the packet.
 8. Theapparatus of claim 5 further comprising: means for dynamically adjustinga maximum packet size for the packets to maintain a maximum packettransmission time across the dynamic communication link approximatelyconstant; and means for rearranging the order of packets to givetime-sensitive packets greater priority if jitter is present.
 9. Anapparatus for adaptively reallocating bandwidth for quality of servicepolicy of a dynamic communication link comprising: a receiver configuredto receive digital information from one or more sources; a processorconfigured to: organize the digital information into packets, eachpacket associated with one of a plurality of service classes; anddynamically adjust a quality of service policy to reallocate the maximumbandwidth per service class if the bandwidth of the dynamiccommunication link changes; and a transmitter configured to transmit thepackets according to a predefined quality of service policy.
 10. Theapparatus of claim 9 wherein the processor is further configured tomonitor the real-time bandwidth characteristics of the dynamiccommunication link.
 11. The apparatus of claim 9 wherein the deliverypriority level associated with each packet is determined by the timingrequirements of the digital information contained in the packet.
 12. Theapparatus of claim 9 therein the processor is further configured to:dynamically adjust a maximum packet size for the packets to maintain amaximum packet transmission time across the dynamic communication linkapproximately constant; and rearrange the order of packets to givetime-sensitive packets greater priority if jitter is present.
 13. Anon-transitory computer readable medium having a set of instructionsstored thereon, the set of instructions being executable by one or moreprocessors and the set of instructions comprising: instructions fororganizing digital information received from a plurality of sources intopackets, each packet associated with one of a plurality of serviceclasses; instructions for dynamically adjusting a quality of servicepolicy to reallocate the maximum bandwidth per service class if thebandwidth of the dynamic communication link changes; and instructionsfor providing the packets for transmission according to a predefinedquality of service policy.
 14. The non-transitory computer readablemedium of claim 13 further comprising: instructions for monitoring thereal-time bandwidth characteristics of the dynamic communication link.15. The non-transitory computer readable medium of claim 13 wherein thedelivery priority level associated with each packet is determined basedon the timing requirements of the digital information contained in thepacket.
 16. The non-transitory computer readable medium of claim 13further comprising: instructions for dynamically adjusting a maximumpacket size for the packets maintain a maximum packet transmission timeacross the dynamic communication link approximately constant; andinstructions for rearranging the order of packets to give time-sensitivepackets greater priority if jitter is present,
 17. A non-transitorycomputer readable medium having a set of instructions stored thereon,the set of instructions being executable by one or more processors andthe set of instructions comprising: instructions for determining whetherjitter is present in a dynamic communication link; and instructions forrearranging the order of digital information packets to givetime-sensitive packets greater priority when jitter is present.
 18. Thenon-transitory computer readable medium of claim 17 further comprising:instructions for determining delivery priorities of a plurality ofdigital information packets.
 19. A non-transitory computer readablemedium having a set of instructions stored thereon, the set ofinstructions being executable by one or more processors and the set ofinstructions comprising: instructions to implement two or more networkstack layers to transmit digital information of one or more serviceclasses across a dynamic communication link; and instructions to sharedynamic link status information from a first network stack layer with asecond network stack layer.
 20. The non-transitory computer readablemedium of claim 19 wherein the first network stack layer is either thephysical layer or data link layer of a network stack and the secondnetwork stack layer is the network layer.
 21. The non-transitorycomputer readable medium of claim 19 further comprising: instructions toobtain real-time link status feedback from a data link layer of thenetwork stack and apply it to quality of service operations at thenetwork layer of the network stack.
 22. An apparatus comprising: meansfor determining whether jitter is present in a dynamic communicationlink; and means for adaptively rearranging the order of digitalinformation packets to give time-sensitive packets greater priority whenjitter is present.
 23. An apparatus comprising: means for implementingtwo or more network stack layers to transmit digital information fromone or more service classes across a dynamic communication link; andmeans for sharing dynamic link status information from a first networkstack layer with a second network stack layer.